On the interpretation of fluorescence anisotropy decays from probe molecules in lipid vesicle systems

Measurements of fluorescence depolarization decays are widely used to obtain information about the molecular order and rotational dynamics of fluorescent probe molecules in membrane systems. This information is obtained by least-squares fits of the experimental data to the predictions of physical models for motion. Here we present a critical review of the ways and means of the data analysis and address the question how and why totally different models such as Brownian rotational diffusion and wobble-in-cone provide such convincing fits to the fluorescence anistropy decay curves. We show that while these models are useful for investigating the general trends in the behavior of the probe molecules, they fail to describe the underlying motional processes. We propose to remedy this situation with a model in which the probe molecules undergo fast, though restricted local motions within a slowly rotating cage in the lipid bilayer structure. The cage may be envisaged as a free volume cavity between the lipid molecules, so that its position and orientation change with the internal conformational motions of the lipid chains. This approach may be considered to be a synthesis of the wobble-in-cone and Brownian rotational diffusion models. Importantly, this compound motion model appears to provide a consistent picture of fluorescent probe behavior in both oriented lipid bilayers and lipid vesicle systems.     

Two photon-induced fluorescence intensity and anisotropy decays of diphenylhexatriene in solvents and lipid bilayers

We measured the fluorescence intensity and anisotropy decays of 1,6-diphenyl-1,3,5-hexatriene (DPH)-labeled membranes resulting from simultaneous two-photon excitation of fluorescence. Comparison of these two-photon data with the more usual one-photon measurements revealed that DPH displayed identical intensity decays, anisotropy decays, and order parameters for one- and two-photon excitation. While the anisotropy data are numerically distinct, they can be compared by use of the factor 10/7, which accounts for the two-photon versus one-photon photoselection. The increased time 0 anisotropy of DPH can result in increased resolution of complex anisotropy decays. Global analysis of the one- and two-photon data reveals consistency with a single apparent angle between the absorption and the emission oscillators. The global anisotropy analysis also suggests that, except for the photoselection factor, the anisotropy decays are the same for one-and two-photon excitation. This ideal behavior of DPH as a two-photon absorber, and its high two-photon cross section, makes DPH a potential probe for confocal two-photon microscopy and other systems where it is advantageous to use long-wavelength (680- to 760-nm) excitation.     

Video fluorescence microscopic techniques to monitor local lipid and phospholipid molecular order and organization in cell membranes during hypoxic injury

Digitized video microscopy is rapidly finding uses in a number of fields of biological investigation because it allows quantitative assessment of physiological functions in intact cells under a variety of conditions. In this review paper, we focus on the rationale for the development and use of quantitative digitized video fluorescence microscopic techniques to monitor the molecular order and organization of lipids and phospholipids in the plasma membrane of single living cells. These include (1) fluorescence polarization imaging microscopy, used to measure plasma membrane lipid order, (2) fluorescence resonance energy transfer (FRET) imaging microscopy, used to detect and monitor phospholipid domain formation, and (3) fluorescence quenching imaging microscopy, used to spatially map fluid and rigid lipid domains. We review both the theoretical as well as practical use of these different techniques and their limits and potential for future developments, and provide as an illustrative example their application in studies of plasma membrane lipid order and topography during hypoxic injury in rat hepatocytes. Each of these methods provides complementary information; in the case of hypoxic injury, they all indicated that hypoxic injury leads to a spatially and temporally heterogeneous alteration in lipid order, topography, and fluidity of the plasma membrane. Hypoxic injury induces the formation of both fluid and rigid lipid domains; the formation of these domains is responsible for loss of the plasma membrane permeability barrier and the onset of irreversible injury (cell death). By defining the mechanisms which lead to alterations in lipid and phospholipid order and organization in the plasma membrane of hypoxic cells, potential sites of intervention to delay, prevent, or rescue cells from hypoxic injury have been identified. Finally, we briefly discuss fluorescence lifetime imaging microscopy (FLIM) and its potential application for studies monitoring local lipid and phospholipid molecular order and organization in cell membranes.     

Influence of lipid composition and membrane curvature on fluorescence and solvent relaxation kinetics in unilamellar vesicles

Time-resolved fluorescence on unilamellar vesicles shows that increasing amounts of anionic, natural lipid lead to a larger increase in polarity close to the headgroups than in the hydrophobic core of the bilayer. The region close to the headgroups is less polar in vesicles containing phosphatic acid rather than phosphatidylserine. A greater membrane curvature increases the mobility of the hydrated headgroups.     

Photo-induced nonthermal melting of amorphous chalcogenides observed by pump and probe x-ray absorption spectroscopy

A new kind of melting phenomenon which is not based on thermal excitation has been observed. X-ray absorption spectroscopy (XAS) experiments under optical pumping provide a “snap-shot” information on the local structure under excitation. We have studied the local structure of chalcogenide glasses such as vitrious selenium and As₂Se₃ under optical excitation and confirmed the local melting phenomenon under light illumination at low temperature. The photo-induced nonthermal melting (PNM) in chalcogenide glasses is interpreted as the result of pairing of excited lone pair electrons during the illumination. Trapped states in this photo-assisted metastable phase result in a local structural disorder which is partially quenched at room temperature. The increased short-range disorder causing Coulomb repulsion is the origin of red shift of the absorption coefficient known as the photodarkening effect. We found that the bond alternation of chalcogens occurs during the photo-excitation.     

A theoretical and experimental 1H NMR spectroscopy study of the stereoelectronic interactions that rule the conformational energies of alanine and valine methyl ester

Amino acids exhibit a bipolar zwitterionic structure (⁺H₃N‐CHR‐COO^?) in solution; hence, conformational studies of these compounds have been limited to the gas phase. The conformational preferences of amino acids have been widely attributed to intramolecular hydrogen bonding, despite steric and hyperconjugative effects. In this work, we propose the conformational study of alanine and valine methyl esters, which do not show zwitterionic structures in solution, by¹H NMR and theoretical calculations. The ³J_HH spin–spin coupling constants and theoretical calculations were found to be in agreement, showing that the interplay between steric hindrance and hyperconjugation is the forces that are responsible for determining the conformational preferences of alanine and valine methyl esters. Copyright © 2013 John Wiley & Sons, Ltd.     

Spectroscopic Properties and Conformational Features of Short Linear Peptides in Solution: A Fluorescence and Molecular Mechanics Investigation

The ground- and excited-state properties of two conformationally constrained hexapeptides of general formula Boc-Bin-A₁-A₂-T-A₁-A₂-OtBu, where A₁ and A₂ are -aminoisobutyric acid (Aib) or L-alanine (Ala), Bin is an optically pure, axially chiral 1,1-binaphthyl-substituted Aib, and T (Toac) is a stable nitroxide free radical-containing Ac6c analog, were investigated in methanol solution. These peptides are denoted as (R)-Bin/Toac and (S)-Bin/Toac, depending on the chirality of the binaphthyl moiety. Electronic spectra in methanol indicate the occurrence of intramolecular exciton interaction between the naphthyl moieties of Bin, and time-resolved fluorescence measurements show a biexponential decay for both peptides examined. According to infrared (IR) absorption data in the NH stretching frequency region, and to earlier X-ray diffraction results on (S)-Bin/Toac in the crystal state, both (R)-Bin/Toac and (S)-Bin/Toac populate a 3₁₀-helix in solution with opposite screw sense, the helical handedness being determined by the chirality of binaphthyl and not by that of the Ala residues in the main chain. The combination of molecular mechanics calculations with fluorescence decay data indicate that the two observed lifetimes for each peptide arise from two conformations having different interprobe distance and orientation, in which electronic energy transfer from excited Bin to Toac takes place.